KR0156093B1 - Automatic buffing hinge using oil pressure - Google Patents

Abstract

The present invention forms a clockwise spiral cam hole on one circumferential wall of the reciprocating tube fixed to the piston installed in the cylinder with a flow path formed at the bottom thereof, and a counterclockwise spiral cam hole is formed on the other circumferential wall to rotate the shaft in a clockwise spiral cam hole. The clockwise spiral cam protrusion is formed to be engaged with each other. The counterclockwise spiral cam hole is inserted by inserting a insertion pin into the cylinder, and a certain amount of oil is introduced into the cylinder where the coil spring is installed on the upper and lower sides. When the door is opened and closed, the reciprocating tube is inserted into the cylinder in the counterclockwise spiral cam slot to prevent the reciprocating tube from rotating according to the rotation of the rotary shaft. Can be moved up and down flexibly while rotating along the cam hole The piston installed in the lower end of the reciprocating pipe receives a certain amount of oil and moves it up and down the piston by the opening and closing valve installed in the flow path and piston, and the piston rotates due to the spring force. When the oil descends and moves to the upper part of the piston, the door closes slowly. At the last closing moment, the door closes temporarily slowly and then closes at a high speed and closes the door completely.

Description

Hydraulically Operated Automatic Shock Hinges

The present invention forms a clockwise spiral cam hole around one side of the reciprocating ear canal in which the piston is installed, and a counterclockwise spiral cam hole is formed on the other side wall. The clockwise helical cam protrusions protruding on the rotating side are installed to be engaged with each other. The counterclockwise helical cam slots are inserted by inserting inserting pins into the cylinders. When the door is opened and closed, the insertion pin inserted into the cylinder in the counterclockwise spiral cam hole prevents the reciprocating pipe from rotating by the spiral cam protrusion formed on the rotating shaft according to the rotation of the rotating shaft when the door is opened and closed. The reciprocating tube follows each helical camhole because it leads to each helical camhole. It can move up and down flexibly while rotating.

Therefore, the oil inflowed into the cylinder by the piston installed at the lower end of the reciprocating pipe receives pressure and moves up and down the piston by the on-off valve installed in the flow path and piston. When the axis of rotation rotates, the piston descends and compresses the oil. When the pressure is moved to the upper part of the piston, the door closes slowly. At the last closing moment, the door is temporarily closed very slowly, and the flow path opens rapidly and closes rapidly. The door is completely closed.

Conventional hydraulically actuated buffer hinge forms a cylinder with the upper part open on the hinge plate and a recess in the center of the bottom, and forms a spiral groove in the same direction symmetrically on the outer periphery of the cylinder and a key in the symmetrically drilled key groove inside the cylinder. Insert the end of the guide pin that is symmetrically coupled from the outside to the inside of the cylinder into the spiral groove formed in the same direction symmetrically on the outer circumference of the piston, and insert the shaft with the through hole at the center of the piston to symmetrically on the outer circumference. The ball valve was installed so that the key inserted into the piston was formed and the lower part of the through hole of the shaft was extended so that it could be pushed by the coil spring, but when the door was opened or closed, the piston moved up and down like the shaft. Heavy loads and incomplete operation make it possible to perform the functions of the hydraulically operated buffer hinge perfectly. In addition, there is a problem of many failure rate, and the shock absorber which closes the door automatically and slowly closes it is installed in the upper part of the door frame and the door, such as a door closer separated from the hinge, so that the shock absorbing action is performed. It is common, but the structure is complicated, the failure rate is high, the installation place is not only affected by the installation place, but the installed shock absorber is exposed to the outside, there was an aesthetic problem.

In order to reduce the above problems, the present invention forms a clockwise spiral cam hole in one circumferential wall of the reciprocating pipe which fixes the piston installed in the cylinder with a flow path formed at the bottom thereof, and forms a counterclockwise spiral cap hole in the other circumferential wall. In the helical helical cap hole, a clockwise helical cam protrusion is formed to be engaged with the rotating shaft. In the counterclockwise helical cam slot, a insertion pin is inserted into the cylinder, and a certain amount of oil is introduced into the cylinder with the coil spring installed at the upper and lower parts. When the door is opened and connected to the door frame and the door to open and close the door, the clockwise spiral cam protrusion formed on the rotating shaft is engaged with the clockwise spiral cam slot formed on the reciprocating pipe in accordance with the rotation of the rotating shaft. Counterclockwise spiral The reciprocating pipe can move up and down flexibly while rotating along each helical cam hole while the insertion pin inserted into the cylinder is inserted into the cylinder and inserted into the cylinder. The oil flowed into the cylinder by a certain amount is compressed and is moved up and down of the piston by the opening and closing valve installed in the flow path and piston by the pressure.In this case, when the door is closed, the rotating shaft rotates by the spring force of the spring, If you lower the piston is lowered to compress the oil by the pressure of the oil is moved to the upper portion of the piston along the narrow flow path to close the door slowly. At this time, at the last closing moment, the door is closed very slowly temporarily and then closes at a high speed at the moment.

1 is a longitudinal cross-sectional view of the present invention.

2 is a partial cross-sectional view of the main operation state of the present invention.

3 is an exploded perspective view of the main body extraction of the present invention.

Figure 4 (a) (b) is a sectional view of the main portion extraction operation state of the present invention.

Figure 5 (a) (b) (c) is a cross-sectional view of the hydraulic operation state of the present invention.

6 is a sectional view of the main part.

* Explanation of symbols for main parts of the drawings

1,1a: connecting piece 2: cylinder

3: on-off valve 3a: conical check valve

4: piston 5: clockwise spiral cam hole

5a: counterclockwise spiral cam hole 6: reciprocating pipe

7: rotating shaft 8: spiral cam protrusion

9: insertion pin 10, 10a: flow path

11: Flow control valve 12,12a: Cap

13,13a: Tubular nut 14,14a: Coil spring

15: spring strength adjustment head

When described in detail by the accompanying drawings of the present invention as described above are as follows.

In the cylinder (2) with one side connecting piece (1), a piston (4) provided with an on-off valve (3) and a check valve (3a) is provided at the lower end, and a spiral cam hole (5) clockwise on one side wall. A reciprocating tube 6 having a counterclockwise spiral cam hole 5a formed on the other circumferential wall, and a spiral cam protrusion 8 protruding from the rotating shaft 7 in a clockwise direction formed in the reciprocating tube 6. It is installed to be engaged with the spiral cam long hole (5) and inserted into the counterclockwise spiral cam long hole (5a) formed on the other side by inserting the insertion pin (9) in the cylinder (2) to guide the reciprocating pipe (6) to move up and down In the lower part of the cylinder 2, the flow paths 10 and 10a are formed to be maintained at a predetermined interval up and down so that the flow paths 10 and 10a can be blocked at a predetermined position when the piston 4 descends. (2) The amount of oil flowing up and down by installing a flow control valve 11 after introducing a certain amount of oil into The caps 12 and 12a attached to the opposite ends of the other connecting piece 1a and fixed to the upper and lower portions of the cylinder 2 with the tubular nuts 13 and 13a, and each cap 12 and 12a. Spring strength adjustment heads (15, 15a) with coil springs (14, 14a) installed inside, one end fixed to cylinder (2) and tubular nut (13a), and the other end fixed to cap (12) (12a). The upper end of the rotating shaft 7 is fixed to the spring strength adjustment head 15a so that the rotating shaft 7 is rotated according to the elastic force of the coil springs 14 and 14a.

When the connecting piece (1) (1a) of the present invention configured as described above is fixed to the door and the door frame and the door is opened, the spring strength adjusting heads (15) (15a) fixed to the caps (12) (12a) attached to both ends of the connecting piece (1a). ) Rotates along the coil spring (14) (14a) is wound and the rotating shaft (7) fixed to the spring strength saving head (15a) fixed to the cap (12a) is rotated accordingly.

The clockwise spiral cam protrusion 8 protruding from the rotating shaft 7 rotated in this manner is engaged with the clockwise spiral cap hole 5 formed in the reciprocating tube 6, so that the reciprocating tube 6 is the rotary shaft 7. In the counterclockwise helical cam hole 5a formed on the other side of the reciprocating tube 6, the insertion pin 9 inserted from the outer circumference of the cylinder 2 is inserted when it is to rotate in accordance with the rotation of the reciprocating tube ( 6, the insertion pin 9 is guided to the counterclockwise spiral cam hole 5a, and the clockwise spiral cam protrusion 8 formed on the rotation shaft 7 is formed in the reciprocating tube 6. Since it is guided to the clockwise spiral cam hole 5 formed on one side, it is moved flexibly while rotating along each spiral cam hole 5 (5a).

Since the piston 4 fixed to the end of the reciprocating pipe 6 which rises here also rises, the oil which flowed into the upper part of the piston 4 which rises in this way receives the compression of the piston 4, As the ball valve 3 installed on the piston 4 opens, a large amount of oil flows into the lower part of the cylinder 2, so that the door can be opened without great force, and the coil spring 14 is wound when the door is closed. By the elasticity of 14a, it tries to close, rotating in the opposite direction.

In this case, when the spring strength adjustment heads 15 and 15a are fixed by rotating left and right, the strength of the coil springs 14 and 14a can be freely adjusted to allow the door to be closed smoothly.

The rotary shaft 7 fixed to the spring strength adjusting heads 15 and 15a by the elastic force of the coil springs 14 and 14a rotates in the opposite direction when the door is opened. The clockwise spiral cam projection piece 8 which protrudes is made to rotate along.

Therefore, when the reciprocating pipe 6 tries to rotate accordingly by the clockwise spiral cam slot 5 engaged with the clockwise spiral cam projection piece 8 formed on the rotation shaft 7, it is driven into the cylinder 2. The reciprocating pipe 6 is guided to each helical cam slot 5 and 5a while being blocked by the insertion pin 9 inserted into the clockwise spiral cam slot 5a. (5) As it descends while rotating along (5a), the ball valve (3) and the check valve (3a) are closed by the pressure that the piston (4) connected to the lower end of the reciprocating pipe (6) compresses the oil of the lower part. Will be sifted.

At this time, the oil flowing into the lower portion of the piston 4 gradually flows into the upper portion of the piston 4 through the flow path 10 formed in the cylinder 2 by the pressure of the piston 4, and thus the door is gradually closed. .

Here, the flow rate can be adjusted by adjusting the flow control valve 11 so that the speed at which the door is closed can be freely adjusted. As such, when the piston is lowered and the door is closed, the door is closed at a certain distance. As the upper and lower circumferential walls block the flow paths 10 and 10a formed to maintain a predetermined interval up and down as shown in FIG. 5B, the closing door is temporarily stopped, and the cylinder 2 and the piston 4 are formed. As the oil rises between the gaps, the door is closed very slowly, and when the flow path 10a formed in the cylinder 2 is opened, a large amount of oil is instantly raised to close the door normally. At this time, the check installed in the piston 4 The valve (3a) opens and touches the bottom of the cylinder (2), causing a large amount of oil to rise momentarily, closing the door at a faster rate and immersing it in the locking device installed on the door frame and door. Will be.

As described above, the present invention allows the buffer to be smoothly operated by hydraulic pressure when the door is closed, while the door is closed very slowly at a certain distance while the door is closed, and momentarily accelerates to be locked in the locking device, and at the same time flow rate and spring It is possible to control the strength of the door, the speed of closing the door is free to control, the structure is simple, the failure rate is extremely small, its life is long, and it is easy to use and install.

Claims (1)

In the cylinder (2) with one side connecting piece (1), a piston (4) provided with an on-off valve (3) and a check valve (3a) is provided at the end, and a spiral cam hole (5) clockwise is provided on one side of the main wall. A reciprocating pipe (6) formed on the other side of the circumferential wall and provided with a counterclockwise spiral cam hole (5a) so that the clockwise helical cam protrusion (8) protruding from the rotating shaft (7) is provided in the reciprocating pipe (6). It is installed to be engaged with the formed clockwise spiral cam hole 5, and the insertion pin 9 is driven into the cylinder 2 and inserted into the counterclockwise spiral cam hole 5a formed on the other side, and the cylinder 2 bottom The flow paths 10 and 10a are formed to maintain a predetermined interval in the upper and lower portions so that the upper and lower peripheral walls of the piston 4 can temporarily block the flow paths 10 and 10a at a predetermined position when the piston 4 descends. The caps 12 and 12a attached to both ends of the other connecting piece 1a are supported by the tubular nuts 13 and 13a at the lower and lower portions of the cylinder 2, respectively. (12) (12a) The spring strength adjustment head fixed in the cylinder (2) and tubular nut (13a) and the other end in the cap (12) (12a) by installing coil springs (14) and (14a) inside. 15) (15a), the hydraulically actuated automatic buffer hinge by inserting and fixing the upper end of the rotary shaft (7) to the spring strength adjustment head (15a).

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